Alex Merced || 2024-09-22

Data Analytics || data apps - streamlit

Introduction

The ability to quickly develop and deploy interactive applications is invaluable. Streamlit is a powerful tool that enables data scientists and developers to create intuitive web apps with minimal code. Coupled with the Python Data Science Notebook Docker Image, which comes pre-loaded with essential data science libraries, setting up a robust environment for building Streamlit apps has never been easier.

What is Streamlit?

Streamlit is an open-source Python library that simplifies the process of creating interactive web applications for data science and machine learning projects. With Streamlit, you can transform your data scripts into shareable web apps in just a few minutes, all using pure Python. There’s no need for front-end development skills or knowledge of web frameworks like Flask or Django.

Key features of Streamlit include:

  • Easy to Use: Build apps with a few lines of code using straightforward APIs.
  • Interactive Widgets: Incorporate sliders, buttons, text inputs, and more to make your app interactive.
  • Real-Time Updates: Automatically update app content when your data or code changes.
  • Data Visualization: Seamlessly integrate with libraries like Matplotlib, Seaborn, Plotly, and Altair for rich visualizations.
  • Deployment Ready: Deploy apps effortlessly on various platforms, including Streamlit Cloud, Heroku, and AWS.

Why Use Streamlit for Data Apps?

Streamlit offers several advantages that make it an ideal choice for developing data applications:

  • Rapid Prototyping: Quickly turn ideas into functional apps without worrying about the underlying web infrastructure.
  • Pythonic Syntax: Write apps entirely in Python, leveraging your existing skills without the need to learn HTML, CSS, or JavaScript.
  • Interactive Data Exploration: Enable users to interact with data through widgets, making it easier to explore datasets and model results.
  • Community and Support: Benefit from a growing community that contributes to a rich ecosystem of plugins and extensions.
  • Open Source: Modify and extend the library to suit your needs, with the assurance of ongoing development and support.

By using Streamlit, data scientists can focus on data analysis and model building while providing stakeholders with interactive tools to visualize and understand the results.

Overview of the Python Data Science Notebook Docker Image

The Python Data Science Notebook Docker Image is a Docker container designed to streamline your data science workflow. Built from the minimal python:3.9-slim base image, it includes a comprehensive suite of pre-installed libraries that cater to various aspects of data science, including data manipulation, machine learning, visualization, and database connectivity.

Key Features:

  • Jupyter Notebook Access: Run and access Jupyter Notebooks through your web browser, facilitating an interactive coding environment.
  • Pre-Installed Libraries:
    • Data Manipulation: pandas, numpy, polars, dask, ibis, pyiceberg, datafusion, sqlframe
    • Machine Learning: scikit-learn, tensorflow, torch, xgboost, lightgbm
    • Visualization: matplotlib, seaborn, plotly
    • Database Access: psycopg2-binary, mysqlclient, sqlalchemy, duckdb, pyarrow
    • Object Storage: boto3, s3fs, minio
    • Utilities: openpyxl, requests, beautifulsoup4, lxml, pyspark, dremio-simple-query
  • User Configuration: Operates under the user pydata with the home directory set to /home/pydata. The working directory is /home/pydata/work.
  • Port Exposure: Exposes port 8888 to allow access to the Jupyter Notebook server.

Benefits:

  • Consistency: Ensure a consistent development environment across different machines and team members.
  • Isolation: Avoid conflicts with other projects and dependencies on your local machine.
  • Portability: Easily move your development environment between systems or deploy it to a server.
  • Extendable: Customize the Docker image by adding more libraries or configurations as needed.

By utilizing this Docker image, you can save time on setup and focus on developing your Streamlit applications, knowing that you have all the necessary tools and libraries at your disposal.

Setting Up the Environment

To get started with building Streamlit applications using the Python Data Science Notebook Docker Image, you’ll need to set up your environment. This involves installing Docker, pulling the Docker image, running the container, and verifying that Streamlit is installed and functioning correctly.

Installing Docker

If Docker is not already installed on your machine, follow these steps:

  1. Download Docker Desktop:

  2. Install Docker:

    • Run the installer and follow the on-screen instructions.
    • For Linux, follow the command-line instructions provided in the installation guide for your distribution.
  3. Verify the Installation:

    Open a terminal or command prompt and run:

   docker --version

You should see the Docker version information displayed, confirming that Docker is installed.

Pulling the alexmerced/datanotebook Docker Image

The alexmerced/datanotebook Docker image includes a comprehensive Python environment with pre-installed data science libraries.

Pull the Docker Image:

In your terminal, execute:

docker pull alexmerced/datanotebook

This command downloads the image from Docker Hub to your local machine.

Confirm the Image is Pulled:

List all Docker images on your system:

docker images

You should see alexmerced/datanotebook listed among the images.

Running the Docker Container with Jupyter Notebook Access

Now, run a Docker container from the image and access the Jupyter Notebook server.

  • Navigate to Your Working Directory

  • Open a terminal and change to the directory where you want your Jupyter Notebooks and Streamlit apps to reside:

cd /path/to/your/project

Run the Docker Container:

Execute the following command:

docker run -p 8888:8888 -p 8501:8501 -v $(pwd):/home/pydata/work alexmerced/datanotebook
  • Port Mapping: -p 8888:8888 maps the container’s port 8888 to your local machine, allowing access to Jupyter Notebook. -p 8501:8501 maps the container’s port 8501 to your local machine, allowing access to Streamlit apps.
  • Volume Mounting: -v $(pwd):/home/pydata/work mounts your current directory into the container, enabling file sharing between your host and the container.

Access Jupyter Notebook:

Open your web browser and navigate to http://localhost:8888.

You should see the Jupyter Notebook interface without needing a password or token.

Verifying the Installation of Streamlit within the Container

Ensure that Streamlit is installed and functioning properly inside the Docker container.

  • Open a New Terminal in Jupyter Notebook.

  • In the Jupyter interface, click on the New dropdown menu and select Terminal.

  • In the terminal, run:

streamlit --version

If Streamlit is installed, the version number will be displayed.

If not installed, install it using:

pip install streamlit

Create a Test Streamlit App:

In the Jupyter interface, click on New and select Text File.

Save the file as app.py in your working directory.

Add the following code to app.py:

import streamlit as st

st.title("Streamlit Test App")
st.write("Congratulations! Streamlit is working inside the Docker container.")

Save the file.

Run the Streamlit App:

In the Jupyter terminal, execute:

streamlit run app.py --server.enableCORS false --server.enableXsrfProtection false --server.port 8501 --server.address 0.0.0.0

Server Flags Explained:

  • --server.enableCORS false: Disables Cross-Origin Resource Sharing protection.
  • --server.enableXsrfProtection false: Disables Cross-Site Request Forgery protection.
  • --server.port 8501: Runs the app on port 8501.
  • --server.address 0.0.0.0: Makes the server accessible externally.

Access the Streamlit App:

Open a new tab in your web browser and navigate to http://localhost:8501.

You should see the Streamlit app displaying the title and message.

Optional: Keep Streamlit Running in the Background:

To keep the Streamlit app running without occupying the terminal, you can run it in the background using nohup:

nohup streamlit run app.py --server.enableCORS false --server.enableXsrfProtection false --server.port 8501 --server.address 0.0.0.0 &

Exiting the Docker Container

In the Terminal Running the Container:

Press Ctrl + C to stop the container.

Alternatively, Use Docker Commands:

  • List running containers
docker ps

Stop the container using its Container ID:

docker stop <container_id>

Summary

You’ve successfully set up your environment:

  • Installed Docker (if necessary).
  • Pulled the alexmerced/datanotebook Docker image.
  • Ran the Docker container with Jupyter Notebook access.
  • Verified that Streamlit is installed and operational within the container.

With this setup, you’re ready to develop and run Streamlit applications in a consistent and isolated environment, leveraging the powerful tools provided by the Docker image.

Getting Started with Streamlit

With your environment set up, it’s time to dive into Streamlit and start building interactive applications. This section will guide you through creating your first Streamlit app, understanding the basic structure of a Streamlit script, and running Streamlit apps from within the Jupyter Notebook provided by the Docker container.

Creating Your First Streamlit App

Let’s begin by creating a simple Streamlit application that displays text and a chart.

  1. Create a New Python Script:

    • In the Jupyter Notebook interface, click on New and select Text File.
    • Save the file as app.py in your working directory (/home/pydata/work).
  2. Write the Streamlit Code:

    Open app.py and add the following code:

   import streamlit as st
   import pandas as pd
   import numpy as np

   st.title("My First Streamlit App")

   st.write("Welcome to my first Streamlit application!")

   # Create a random dataframe
   df = pd.DataFrame(
       np.random.randn(20, 3),
       columns=['Column A', 'Column B', 'Column C']
   )

   st.write("Here is a random dataframe:")
   st.dataframe(df)

   st.write("Line chart of the data:")
   st.line_chart(df)

Explanation:

  • Imports necessary libraries.
  • Sets the title and writes introductory text.
  • Generates a random DataFrame.
  • Displays the DataFrame and a line chart based on the data.

Save the Script:

  • Ensure that you save app.py after adding the code.

Understanding the Basic Structure of a Streamlit Script

A Streamlit script is a standard Python script with the streamlit library functions to create interactive elements.

  • Import Streamlit:
import streamlit as st

Set the Title and Headers:

st.title("App Title")
st.header("This is a header")
st.subheader("This is a subheader")

Write Text:

st.text("This is a simple text.")
st.markdown("This is a text with **markdown** formatting.")

Display Data:

st.dataframe(df)  # Displays an interactive table
st.table(df)      # Displays a static table

Display Charts:

st.line_chart(data)
st.bar_chart(data)
st.area_chart(data)

Add Interactive Widgets:

name = st.text_input("Enter your name:")
st.write(f"Hello, {name}!")

age = st.slider("Select your age:", 0, 100)
st.write(f"You are {age} years old.")

Layout Elements:

with st.sidebar:
    st.write("This is the sidebar.")

col1, col2 = st.columns(2)
col1.write("Content in column 1")
col2.write("Content in column 2")

Running Streamlit Apps from Within the Jupyter Notebook

To run your Streamlit app within the Docker container and access it from your host machine:

Open a Terminal in Jupyter Notebook:

In the Jupyter interface, click on New and select Terminal.

Navigate to the Working Directory:

cd /home/pydata/work

Run the Streamlit App:

Execute the following command:

streamlit run app.py --server.enableCORS false --server.enableXsrfProtection false --server.port 8501 --server.address 0.0.0.0

Explanation of Flags:

  • --server.enableCORS false: Disables Cross-Origin Resource Sharing protection.
  • --server.enableXsrfProtection false: Disables Cross-Site Request Forgery protection.
  • --server.port 8501: Sets the port to 8501.
  • --server.address 0.0.0.0: Makes the app accessible externally.

Access the Streamlit App:

  • Open your web browser and navigate to http://localhost:8501.

You should see your Streamlit app running. Interact with the App:

  • Modify app.py to add more features or interactive elements.
  • Save the changes, and the app will automatically reload in the browser.

Tips for Running Streamlit in Docker

Expose the Correct Port:

When running the Docker container, ensure you expose the port used by Streamlit. If you use port 8501, run the container with:

docker run -p 8888:8888 -p 8501:8501 -v $(pwd):/home/pydata/work alexmerced/datanotebook

Running Multiple Apps:

Use different ports for each app and expose them accordingly.

Background Execution:

To run the Streamlit app without tying up the terminal, use:

nohup streamlit run app.py --server.enableCORS false --server.enableXsrfProtection false --server.port 8501 --server.address 0.0.0.0 &

This runs the app in the background and outputs logs to nohup.out.

Summary

In this section, you:

  • Created your first Streamlit app using the pre-configured Docker environment.
  • Learned about the basic structure and components of a Streamlit script.
  • Ran the Streamlit app from within the Jupyter Notebook environment.
  • Accessed and interacted with the app via your web browser.

With these foundational skills, you’re ready to explore more advanced features of Streamlit to build sophisticated data applications.

Building Interactive Data Visualizations

Data visualization is a crucial aspect of data analysis and communication. Streamlit simplifies the process of creating interactive and dynamic visualizations that can help users explore and understand data more effectively. In this section, we’ll explore how to use Streamlit’s built-in functions and integrate popular visualization libraries to build interactive data visualizations.

Using Streamlit’s Built-in Chart Functions

Streamlit provides easy-to-use functions for creating basic charts directly from data structures like Pandas DataFrames and NumPy arrays.

Line Chart

import streamlit as st
import pandas as pd
import numpy as np

# Generate random data
data = np.random.randn(100, 3)
columns = ['Feature A', 'Feature B', 'Feature C']
df = pd.DataFrame(data, columns=columns)

# Display line chart
st.line_chart(df)

Explanation: The st.line_chart() function takes a DataFrame or array-like object and renders an interactive line chart.

Bar Chart

# Display bar chart
st.bar_chart(df)

Explanation: st.bar_chart() displays a bar chart. It’s useful for categorical data or comparing different groups.

Area Chart

# Display area chart
st.area_chart(df)

Explanation: st.area_chart() creates an area chart, which is similar to a line chart but with the area below the line filled.

Customizing Charts with Altair

For more advanced visualizations, Streamlit supports libraries like Altair, which provides a declarative statistical visualization library for Python.

Creating an Altair Chart

import altair as alt

# Create an Altair chart
chart = alt.Chart(df.reset_index()).mark_circle(size=60).encode(
    x='index',
    y='Feature A',
    color='Feature B',
    tooltip=['Feature A', 'Feature B', 'Feature C']
).interactive()

st.altair_chart(chart, use_container_width=True)

Explanation: This code creates an interactive scatter plot using Altair, where you can hover over points to see tooltips.

Interactive Widgets for User Input

Streamlit allows you to add widgets that enable users to interact with your visualizations.

Adding a Slider

# Slider to select number of data points
num_points = st.slider('Select number of data points', min_value=10, max_value=100, value=50)

# Generate data based on slider
data = np.random.randn(num_points, 3)
df = pd.DataFrame(data, columns=columns)

# Display updated chart
st.line_chart(df)

Explanation: The slider widget allows users to select the number of data points, and the chart updates accordingly.

Selectbox for Options

# Selectbox to choose a feature
feature = st.selectbox('Select a feature to display', columns)

# Display the selected feature
st.line_chart(df[feature])

Explanation: The selectbox lets users choose which feature to visualize.

Integrating Plotly for Advanced Visualizations

Plotly is another powerful library for creating interactive graphs.

Plotly Example

import plotly.express as px

# Create a Plotly figure
fig = px.scatter(df, x='Feature A', y='Feature B', size='Feature C', color='Feature C', hover_name='Feature C')

# Display the Plotly figure in Streamlit
st.plotly_chart(fig, use_container_width=True)

Explanation: This code creates an interactive scatter plot with Plotly, which includes zooming, panning, and tooltips.

Combining Widgets and Visualizations

You can combine multiple widgets and charts to create a rich interactive experience.

Example: Interactive Data Filtering

# Multiselect to choose features
selected_features = st.multiselect('Select features to visualize', columns, default=columns)

# Checkbox to toggle data normalization
normalize = st.checkbox('Normalize data')

# Process data based on user input
if normalize:
    df_normalized = (df - df.mean()) / df.std()
    data_to_plot = df_normalized[selected_features]
else:
    data_to_plot = df[selected_features]

# Display line chart of selected features
st.line_chart(data_to_plot)

Explanation: Users can select which features to visualize and whether to normalize the data, and the chart updates accordingly.

Best Practices for Interactive Visualizations

  • Limit Data Size: Large datasets can slow down your app. Consider sampling or aggregating data.
  • Use Caching: Use @st.cache_data decorator to cache data loading and computation functions.
  • Provide Instructions: Use st.markdown() or st.write() to guide users on how to interact with your app.
  • Optimize Layout: Organize widgets and charts using columns and expanders for a clean interface.

Example of Layout Optimization

# Create columns
col1, col2 = st.columns(2)

with col1:
    st.header('User Inputs')
    # Add widgets here
    num_points = st.slider('Number of points', 10, 100, 50)
    feature = st.selectbox('Feature', columns)

with col2:
    st.header('Visualization')
    # Generate and display chart
    data = np.random.randn(num_points, len(columns))
    df = pd.DataFrame(data, columns=columns)
    st.line_chart(df[feature])

Explanation: This layout separates user inputs and visualizations into two columns, making the app more organized.

Summary

In this section, you’ve learned how to:

  • Use Streamlit’s built-in chart functions to create quick visualizations.
  • Customize charts using Altair and Plotly for more advanced visualizations.
  • Add interactive widgets like sliders and selectboxes to make your visualizations dynamic.
  • Combine widgets and charts to build a user-friendly data exploration tool.

By leveraging these features, you can create powerful interactive applications that make data exploration and analysis more accessible to your audience.

Advanced Streamlit Features

As you become more familiar with Streamlit, you’ll discover a wealth of advanced features that allow you to build more sophisticated and powerful applications. In this section, we’ll delve into some of these capabilities, including state management, dynamic content creation, file handling, and performance optimization through caching.

State Management with st.session_state

Streamlit runs your script from top to bottom every time a user interacts with a widget. To maintain state across these reruns, you can use st.session_state, which is a dictionary-like object that persists throughout the user’s session.

Example: Counter Application

import streamlit as st

# Initialize counter in session state
if 'counter' not in st.session_state:
    st.session_state.counter = 0

# Increment counter on button click
if st.button('Increment'):
    st.session_state.counter += 1

st.write(f"Counter value: {st.session_state.counter}")

Explanation: The counter value is stored in st.session_state.counter, ensuring it persists across interactions.

Dynamic Content with st.expander and st.tabs

Streamlit provides layout elements to organize content and improve user experience.

Using st.expander

import streamlit as st

st.write("This is visible content")

with st.expander("Click to expand"):
    st.write("This content is hidden by default")

Explanation: st.expander creates a collapsible section that users can expand or collapse.

Using st.tabs

import streamlit as st

tab1, tab2 = st.tabs(["Tab 1", "Tab 2"])

with tab1:
    st.write("Content in Tab 1")

with tab2:
    st.write("Content in Tab 2")

Explanation: st.tabs allows you to organize content into tabs for better navigation.

Uploading and Handling Files with st.file_uploader

Allow users to upload files directly into your app for processing.

Example: CSV File Uploader

import streamlit as st
import pandas as pd

uploaded_file = st.file_uploader("Choose a CSV file", type="csv")

if uploaded_file is not None:
    df = pd.read_csv(uploaded_file)
    st.write("Uploaded Data:")
    st.dataframe(df)

Explanation: Users can upload a CSV file, which the app reads and displays as a DataFrame.

Caching with @st.cache_data for Performance Optimization

Heavy computations or data loading can slow down your app. Use caching to store results and avoid redundant processing.

Using @st.cache_data

import streamlit as st
import pandas as pd

@st.cache_data
def load_data(url):
    return pd.read_csv(url)

data_url = 'https://path-to-large-dataset.csv'
df = load_data(data_url)
st.write("Data loaded successfully")
st.dataframe(df.head())

Explanation: The @st.cache_data decorator caches the load_data function’s output, improving performance on subsequent runs.

Customizing the App Layout

Enhance user experience by customizing your app’s layout and appearance.

Setting Page Configuration

import streamlit as st

st.set_page_config(
    page_title="Advanced Streamlit Features",
    page_icon="🚀",
    layout="wide",
    initial_sidebar_state="expanded",
)

Explanation: st.set_page_config sets global configurations like the page title, icon, layout, and sidebar state.

Using Columns and Containers

import streamlit as st

col1, col2 = st.columns(2)

with col1:
    st.header("Column 1")
    st.write("Content for the first column")

with col2:
    st.header("Column 2")
    st.write("Content for the second column")

Explanation: Columns help organize content side by side.

Theming and Styling

Apply custom themes to match your app’s branding or preferred aesthetics.

Applying a Custom Theme

Create a .streamlit/config.toml file in your app directory with the following content:

[theme]
primaryColor="#d33682"
backgroundColor="#002b36"
secondaryBackgroundColor="#586e75"
textColor="#ffffff"
font="sans serif"

Explanation: The theme settings adjust the app’s color scheme and font.

Interactive Widgets for Advanced User Input

Streamlit offers a variety of widgets for complex user interactions.

Date Input and Time Input

import streamlit as st

date = st.date_input("Select a date")
time = st.time_input("Select a time")

st.write(f"You selected {date} at {time}")

Explanation: Allows users to input dates and times.

Color Picker

import streamlit as st

color = st.color_picker('Pick A Color', '#00f900')
st.write('The current color is', color)

Explanation: Users can select a color, which can be used in visualizations or styling. Advanced Callbacks and Event Handling Respond to user interactions with callbacks.

Using Button Callbacks

import streamlit as st

def on_button_click():
    st.write("Button was clicked!")

st.button("Click Me", on_click=on_button_click)

Explanation: The on_click parameter specifies a function to execute when the button is clicked.

Integrating with External APIs

Fetch and display data from external sources.

Example: Fetching Data from an API

import streamlit as st
import requests

st.write("Fetch data from an API")

response = requests.get('https://api.example.com/data')
if response.status_code == 200:
    data = response.json()
    st.write(data)
else:
    st.error("Failed to fetch data")

Explanation: Uses the requests library to fetch data from an API and display it.

Real-Time Data Updates with WebSockets

Streamlit supports bi-directional communication for real-time updates.

Using st.experimental_get_query_params

import streamlit as st

params = st.experimental_get_query_params()
st.write("Query parameters:", params)

Explanation: Access query parameters from the URL to control app behavior dynamically.

Modularizing Code with Components

Break down your app into reusable components.

Creating a Custom Component

# components.py
import streamlit as st

def display_header():
    st.title("Advanced Streamlit Features")
    st.write("This is a custom component")

# main app
import streamlit as st
from components import display_header

display_header()
st.write("Main app content")

Explanation: Organize code by splitting it into modules for better maintainability.

Localization and Internationalization

Make your app accessible to a global audience.

Setting the Language

import streamlit as st

st.write("Hello, World!")

# Use gettext or other localization libraries for translations

Explanation: While Streamlit doesn’t provide built-in localization, you can use Python’s localization libraries.

Accessibility Features

Ensure your app is usable by people with disabilities.

  • Use Semantic HTML: Streamlit automatically generates accessible HTML elements.

  • Provide Alt Text: When displaying images, use the caption parameter.

st.image('image.png', caption='Descriptive text')

Summary

In this section, we’ve explored several advanced features of Streamlit that empower you to build more interactive and efficient applications:

  • State Management: Use st.session_state to preserve data across user interactions.
  • Dynamic Layouts: Organize content with expanders, tabs, columns, and containers.
  • File Handling: Allow users to upload and interact with files directly in the app.
  • Performance Optimization: Improve app speed with caching decorators like @st.cache_data.
  • Customization: Enhance the look and feel with custom themes and page configurations.
  • Advanced Widgets: Utilize a variety of input widgets for richer user interactions.
  • External Integrations: Connect your app to external APIs and services.
  • Code Organization: Modularize your code for better readability and maintenance.
  • Global Reach: Consider localization and accessibility to reach a wider audience.

By mastering these advanced features, you can create sophisticated Streamlit applications that provide a seamless and engaging user experience.

Integrating Machine Learning Models

Streamlit excels at making machine learning models accessible through interactive web applications. In this section, we’ll explore how to integrate machine learning models into your Streamlit apps using the pre-installed libraries in the Python Data Science Notebook Docker Image, such as TensorFlow, PyTorch, and scikit-learn.

Loading Pre-trained Models with TensorFlow and PyTorch

The Docker image comes with TensorFlow and PyTorch installed, allowing you to work with complex neural network models.

Using TensorFlow

Loading a Pre-trained Model

import streamlit as st
import tensorflow as tf

# Load a pre-trained model, e.g., MobileNetV2
model = tf.keras.applications.MobileNetV2(weights='imagenet')

st.write("Model loaded successfully.")

Making Predictions

from tensorflow.keras.applications.mobilenet_v2 import preprocess_input, decode_predictions
from PIL import Image
import numpy as np

uploaded_file = st.file_uploader("Upload an image", type=["jpg", "jpeg", "png"])

if uploaded_file is not None:
    # Load and preprocess the image
    image = Image.open(uploaded_file)
    st.image(image, caption='Uploaded Image', use_column_width=True)

    img = image.resize((224, 224))
    img_array = np.array(img)
    img_array = preprocess_input(img_array)
    img_array = np.expand_dims(img_array, axis=0)

    # Make prediction
    predictions = model.predict(img_array)
    results = decode_predictions(predictions, top=3)[0]

    # Display predictions
    st.write("Top Predictions:")
    for i, res in enumerate(results):
        st.write(f"{i+1}. {res[1]}: {round(res[2]*100, 2)}%")

Explanation: Users can upload an image, and the app displays the top predictions from the pre-trained MobileNetV2 model.

Using PyTorch

Loading a Pre-trained Model

import streamlit as st
import torch
from torchvision import models, transforms

# Load a pre-trained ResNet model
model = models.resnet18(pretrained=True)
model.eval()

st.write("PyTorch model loaded successfully.")

Making Predictions

from PIL import Image
import torchvision.transforms as T

uploaded_file = st.file_uploader("Upload an image", type=["jpg", "jpeg", "png"])

if uploaded_file is not None:
    # Load and preprocess the image
    image = Image.open(uploaded_file)
    st.image(image, caption='Uploaded Image', use_column_width=True)

    preprocess = T.Compose([
        T.Resize(256),
        T.CenterCrop(224),
        T.ToTensor(),
        T.Normalize(
            mean=[0.485, 0.456, 0.406], 
            std=[0.229, 0.224, 0.225]
        )
    ])
    img_t = preprocess(image)
    batch_t = torch.unsqueeze(img_t, 0)

    # Make prediction
    with torch.no_grad():
        out = model(batch_t)
    probabilities = torch.nn.functional.softmax(out[0], dim=0)

    # Load labels
    with open("imagenet_classes.txt") as f:
        labels = [line.strip() for line in f.readlines()]

    # Show top 3 predictions
    top3_prob, top3_catid = torch.topk(probabilities, 3)
    st.write("Top Predictions:")
    for i in range(top3_prob.size(0)):
        st.write(f"{i+1}. {labels[top3_catid[i]]}: {round(top3_prob[i].item()*100, 2)}%")

Note: Ensure that the imagenet_classes.txt file is available in your working directory.

Building a Simple Prediction App with scikit-learn

Let’s build a simple regression app using scikit-learn.

Training a Model

import streamlit as st
from sklearn.datasets import load_boston
from sklearn.ensemble import RandomForestRegressor
from sklearn.model_selection import train_test_split

# Load dataset
data = load_boston()
X = data.data
y = data.target

# Split data
X_train, X_test, y_train, y_test = train_test_split(X, y, test_size=0.2)

# Train model
model = RandomForestRegressor()
model.fit(X_train, y_train)

st.write("Model trained successfully.")

Making Predictions with User Input

import numpy as np

st.header("Boston Housing Price Prediction")

# Feature input sliders
CRIM = st.number_input('Per capita crime rate by town', min_value=0.0, value=0.1)
ZN = st.number_input('Proportion of residential land zoned for lots over 25,000 sq.ft.', min_value=0.0, value=0.0)
# ... add inputs for other features

# For brevity, we'll use default values for the rest of the features
input_features = np.array([[CRIM, ZN] + [0]*(X.shape[1]-2)])

# Predict
prediction = model.predict(input_features)
st.write(f"Predicted median value of owner-occupied homes: ${prediction[0]*1000:.2f}")

Explanation: Users can input values for features, and the app predicts housing prices.

Visualizing Model Outputs and Performance Metrics

Visualizations help in understanding model performance.

Displaying Metrics

from sklearn.metrics import mean_squared_error, r2_score

# Predict on test set
y_pred = model.predict(X_test)

# Calculate metrics
mse = mean_squared_error(y_test, y_pred)
r2 = r2_score(y_test, y_pred)

# Display metrics
st.write("Model Performance on Test Set:")
st.write(f"Mean Squared Error: {mse:.2f}")
st.write(f"R² Score: {r2:.2f}")

Plotting Actual vs. Predicted Values

import pandas as pd

df = pd.DataFrame({'Actual': y_test, 'Predicted': y_pred})

st.write("Actual vs. Predicted Values")
st.line_chart(df)

Explanation: The line chart shows how closely the model’s predictions match the actual values.

Tips for Integrating Machine Learning Models in Streamlit

Model Serialization: For complex models, consider saving and loading models using joblib or pickle to avoid retraining every time.

import joblib

# Save model
joblib.dump(model, 'model.joblib')

# Load model
model = joblib.load('model.joblib')

Use Caching for Models: Cache the model loading or training functions to improve performance.

@st.cache_resource
def load_model():
    # Load or train model
    return model

Handle Large Models: Be mindful of resource limitations. Use efficient data structures and consider offloading heavy computations.

Provide Clear Instructions: Guide users on how to interact with the app, especially when expecting specific input formats.

Summary

In this section, you’ve learned how to:

  • Load and use pre-trained models with TensorFlow and PyTorch in your Streamlit apps.
  • Build a simple prediction app using scikit-learn.
  • Collect user input to make predictions and display results.
  • Visualize model outputs and performance metrics to evaluate model effectiveness.

By integrating machine learning models into your Streamlit applications, you can create powerful tools that make complex models accessible to end-users in an interactive and user-friendly manner.

Database Connectivity

In many data science projects, interacting with databases is essential for retrieving, processing, and storing data. Streamlit, combined with the powerful libraries included in the Python Data Science Notebook Docker Image, makes it straightforward to connect to various databases and integrate them into your applications. In this section, we’ll explore how to connect to databases using sqlalchemy, psycopg2, and specifically how to interact with Dremio using the dremio-simple-query library.

Connecting to Dremio Using dremio-simple-query

Dremio is a data lakehouse platform that enables you to govern, join, and accelerate queries across various data sources such as Iceberg, Delta Lake, S3, JSON, CSV, RDBMS, and more. The dremio-simple-query library simplifies querying a Dremio source using Apache Arrow Flight, providing performant data retrieval for analytics.

Installing the dremio-simple-query Library

First, ensure that the dremio-simple-query library is installed in your environment:

pip install dremio-simple-query

Setting Up the Connection to Dremio

To connect to Dremio, you’ll need to obtain your Dremio Arrow Flight endpoint and an authentication token.

Obtaining the Arrow Flight Endpoint

  • Dremio Cloud (NA): grpc+tls://data.dremio.cloud:443
  • Dremio Cloud (EU): grpc+tls://data.eu.dremio.cloud:443
  • Dremio Software (SSL): grpc+tls://<ip-address>:32010
  • Dremio Software (No SSL): grpc://<ip-address>:32010

Getting Your Authentication Token

  • Dremio Cloud: Obtain the token from the Dremio interface or via the REST API.
  • Dremio Software: Obtain the token using the REST API.

You can use the get_token function from the dremio-simple-query library to retrieve the token programmatically.

Connecting to Dremio

import streamlit as st
from dremio_simple_query.connect import get_token, DremioConnection
from os import getenv
from dotenv import load_dotenv

# Load environment variables from a .env file (optional)
load_dotenv()

# Retrieve Dremio credentials and endpoints
username = st.secrets["dremio_username"]
password = st.secrets["dremio_password"]
arrow_endpoint = st.secrets["dremio_arrow_endpoint"]  # e.g., "grpc+tls://data.dremio.cloud:443"
login_endpoint = st.secrets["dremio_login_endpoint"]  # e.g., "https://your-dremio-server:9047/apiv2/login"

# Get authentication token
payload = {
    "userName": username,
    "password": password
}
token = get_token(uri=login_endpoint, payload=payload)

# Establish connection to Dremio
dremio = DremioConnection(token, arrow_endpoint)

# Test the connection
try:
    st.success("Successfully connected to Dremio.")
except Exception as e:
    st.error(f"Failed to connect to Dremio: {e}")

Note: Ensure that you securely manage your credentials using Streamlit’s secrets management or environment variables.

Querying Data from Dremio

You can now query data from Dremio and retrieve it in various formats.

Retrieving Data as an Arrow Table

# Query data and get a FlightStreamReader object
stream = dremio.toArrow("SELECT * FROM your_space.your_table LIMIT 100")

# Convert the stream to an Arrow Table
arrow_table = stream.read_all()

# Optionally, display the data in Streamlit
df = arrow_table.to_pandas()
st.write("Data from Dremio:")
st.dataframe(df)

Retrieving Data as a Pandas DataFrame

# Directly get a Pandas DataFrame
df = dremio.toPandas("SELECT * FROM your_space.your_table LIMIT 100")
st.write("Data from Dremio:")
st.dataframe(df)

Retrieving Data as a Polars DataFrame

# Get a Polars DataFrame
df_polars = dremio.toPolars("SELECT * FROM your_space.your_table LIMIT 100")
st.write("Data from Dremio (Polars DataFrame):")
st.write(df_polars)

Querying with DuckDB

You can leverage DuckDB for in-memory analytics on the data retrieved from Dremio.

Using the DuckDB Relation API

# Retrieve data as a DuckDB relation
duck_rel = dremio.toDuckDB("SELECT * FROM your_space.your_table LIMIT 100")

# Perform queries on the DuckDB relation
result = duck_rel.filter("column_name > 50").df()

# Display the result
st.write("Filtered Data using DuckDB:")
st.dataframe(result)

Querying Arrow Objects with DuckDB

Alternatively, you can query Arrow Tables using DuckDB:

import duckdb

# Get data from Dremio as an Arrow Table
stream = dremio.toArrow("SELECT * FROM your_space.your_table LIMIT 100")
arrow_table = stream.read_all()

# Create a DuckDB connection
con = duckdb.connect()

# Register the Arrow Table with DuckDB
con.register("dremio_table", arrow_table)

# Perform SQL queries using DuckDB
query = "SELECT * FROM dremio_table WHERE column_name > 50"
result = con.execute(query).fetch_df()

# Display the result
st.write("Filtered Data using DuckDB on Arrow Table:")
st.dataframe(result)

Best Practices for Using Dremio with Streamlit

  • Secure Credentials: Always handle your Dremio credentials securely. Use Streamlit’s secrets management or environment variables to avoid hardcoding sensitive information.
  • Efficient Data Retrieval: Optimize your SQL queries to retrieve only the necessary data. Use LIMIT clauses and filters to reduce data transfer and improve performance.
  • Error Handling: Implement try-except blocks to manage exceptions and provide informative error messages to users.
  • Environment Configuration: Ensure that your arrow_endpoint and login_endpoint are correctly configured based on your Dremio deployment (Cloud or Software, with or without SSL).

Connecting to Databases Using sqlalchemy and psycopg2

In addition to Dremio, you might need to connect to other databases like PostgreSQL or MySQL. The Docker image comes with sqlalchemy, psycopg2-binary, and other database drivers pre-installed.

Setting Up a Connection to a PostgreSQL Database

from sqlalchemy import create_engine
import pandas as pd

# Database connection parameters
DB_USER = st.secrets["db_user"]
DB_PASSWORD = st.secrets["db_password"]
DB_HOST = st.secrets["db_host"]
DB_PORT = st.secrets["db_port"]
DB_NAME = st.secrets["db_name"]

# Create a database engine
engine = create_engine(f'postgresql+psycopg2://{DB_USER}:{DB_PASSWORD}@{DB_HOST}:{DB_PORT}/{DB_NAME}')

# Test the connection
try:
    with engine.connect() as connection:
        st.success("Successfully connected to the PostgreSQL database.")
except Exception as e:
    st.error(f"Failed to connect to the database: {e}")

Querying Data from the Database

# Sample query
query = "SELECT * FROM your_table LIMIT 10"

# Execute the query and load data into a DataFrame
df = pd.read_sql(query, engine)

# Display the data
st.write("Data from PostgreSQL:")
st.dataframe(df)

Handling Large Datasets with Dask

When dealing with large datasets, performance can become an issue. Dask is a parallel computing library that integrates with Pandas to handle larger-than-memory datasets efficiently.

Using Dask to Query Large Tables

import dask.dataframe as dd

# Read data from SQL using Dask
df = dd.read_sql_table(
    table='large_table',
    uri=f'postgresql+psycopg2://{DB_USER}:{DB_PASSWORD}@{DB_HOST}:{DB_PORT}/{DB_NAME}',
    index_col='id'
)

# Perform computations with Dask DataFrame
filtered_df = df[df['value'] > 100]

# Compute the result and convert to Pandas DataFrame
result = filtered_df.compute()

# Display the result
st.write("Filtered Data:")
st.dataframe(result)

Best Practices for Database Connectivity

  • Secure Credentials: Use Streamlit’s secrets management or environment variables to store sensitive information.
  • Parameterized Queries: Always use parameterized queries to prevent SQL injection.
  • Connection Management: Use context managers (with statements) to ensure connections are properly closed.
  • Error Handling: Implement try-except blocks to handle exceptions and provide user-friendly error messages.
  • Limit Data Fetching: When displaying data in the app, limit the number of rows fetched to prevent performance issues.

Summary

In this section, you’ve learned how to:

  • Connect to Dremio using the dremio-simple-query library and retrieve data efficiently using Apache Arrow Flight.
  • Query data from Dremio and convert it into various formats such as Arrow Tables, Pandas DataFrames, Polars DataFrames, and DuckDB relations.
  • Utilize DuckDB for in-memory analytics on data retrieved from Dremio.
  • Connect to other databases like PostgreSQL using sqlalchemy and psycopg2.
  • Handle large datasets efficiently using Dask. Implement best practices for secure and efficient database connectivity.

By integrating Dremio and other data systems into your Streamlit applications, you can create powerful data-driven apps that interact with live data sources, enabling real-time analysis and insights.

Deploying Streamlit Apps

With your Streamlit app developed and tested within the Docker environment, the next step is to deploy it so that others can access and use it. Deploying Streamlit apps can be done in several ways, including running the app locally, containerizing it with Docker, and deploying it to cloud platforms like Streamlit Community Cloud, Heroku, AWS, or other hosting services.

In this section, we’ll explore how to:

  • Run your Streamlit app outside of Jupyter Notebook
  • Containerize your Streamlit app with Docker
  • Deploy your app to cloud platforms

Running Streamlit Apps Outside of Jupyter Notebook

While developing within Jupyter Notebook is convenient, deploying your app typically involves running it as a standalone script.

Steps to Run the App Locally

  1. Ensure Streamlit is Installed

    If you followed the previous sections, Streamlit should already be installed in your Docker container. If not, install it using:

   pip install streamlit

Exit the Jupyter Notebook Environment

  • Stop the Jupyter Notebook server if it’s still running.

  • Navigate to Your App Directory

  • Open a terminal and navigate to the directory containing your app.py file:

cd /home/pydata/work

Run the Streamlit App

Execute the following command:

streamlit run app.py

This command starts the Streamlit server and serves your app at http://localhost:8501 by default.

Access the App in Your Browser

Open your web browser and navigate to http://localhost:8501 to interact with your app.

Containerizing Your Streamlit App with Docker

Containerizing your app ensures consistency across different environments and simplifies deployment.

Creating a Dockerfile for Your Streamlit App

  • Create a Dockerfile

  • In your app directory, create a file named Dockerfile with the following content:

# Use the official Python image as base
FROM python:3.9-slim

# Set the working directory
WORKDIR /app

# Copy the requirements file
COPY requirements.txt .

# Install dependencies
RUN pip install --no-cache-dir -r requirements.txt

# Copy the rest of the application code
COPY . .

# Expose the port Streamlit uses
EXPOSE 8501

# Run the Streamlit app
CMD ["streamlit", "run", "app.py", "--server.port=8501", "--server.address=0.0.0.0"]

Create a requirements.txt File

List all your Python dependencies in a file named requirements.txt:

streamlit
pandas
numpy
# Add any other dependencies your app requires

Build the Docker Image

In your terminal, run:

docker build -t my-streamlit-app .

This builds the Docker image and tags it as my-streamlit-app.

Run the Docker Container

docker run -p 8501:8501 my-streamlit-app

Maps port 8501 in the container to port 8501 on your host machine.

Access the App

Open your web browser and navigate to http://localhost:8501.

Pushing the Docker Image to a Registry (Optional)

If you plan to deploy your app using Docker images, you may need to push it to a Docker registry like Docker Hub or a private registry.

# Tag the image for Docker Hub
docker tag my-streamlit-app your-dockerhub-username/my-streamlit-app


# Log in to Docker Hub
docker login

# Push the image
docker push your-dockerhub-username/my-streamlit-app

Deploying to Cloud Platforms

There are several cloud platforms that support deploying Streamlit apps. Below, we’ll cover deploying to Streamlit Community Cloud, Heroku, and AWS Elastic Beanstalk.

Deploying to Streamlit Community Cloud

Streamlit offers a free hosting service for public GitHub repositories.

  • Push Your App to GitHub

  • Ensure your app code is in a GitHub repository.

  • Sign Up for Streamlit Community Cloud

  • Go to streamlit.io/cloud and sign up using your GitHub account.

  • Deploy Your App

  • Click on “New app”.

  • Select your GitHub repository and branch.

  • Specify the location of your app.py file.

  • Click “Deploy”.

  • Access Your App

Once deployed, you’ll receive a URL where your app is hosted.

Deploying to Heroku

Heroku is a cloud platform that supports deploying applications using Docker.

Create a Procfile

In your app directory, create a file named Procfile with the following content:

web: streamlit run app.py --server.port=$PORT --server.address=0.0.0.0
Create a requirements.txt File
  • Ensure you have a requirements.txt file listing your dependencies.

  • Initialize a Git Repository

If you haven’t already:

git init
git add .
git commit -m "Initial commit"
Create a Heroku App

Install the Heroku CLI and log in:

heroku login

Create a new app:

heroku create your-app-name

Deploy Your App

Push your code to Heroku:

git push heroku master

Scale the Web Process

heroku ps:scale web=1

Access Your App

heroku open

Deploying to AWS Elastic Beanstalk

AWS Elastic Beanstalk supports deploying applications in Docker containers.

  • Install the AWS Elastic Beanstalk CLI

  • Follow the official AWS documentation to install the EB CLI.

  • Initialize Elastic Beanstalk

eb init -p docker my-streamlit-app
Create an Environment
eb create my-streamlit-env
Deploy Your App
eb deploy
Access Your App
eb open

Deploying with Other Services

You can deploy your Streamlit app using other platforms like:

  • Google Cloud Run: For serverless container deployments.
  • Azure App Service: For deploying web apps on Azure.
  • Kubernetes: For scalable and managed deployments.
  • Docker Compose: For multi-container applications.

Example: Deploying to Google Cloud Run

Build and Push the Docker Image to Google Container Registry

# Build the Docker image
docker build -t gcr.io/your-project-id/my-streamlit-app .

# Push the image
docker push gcr.io/your-project-id/my-streamlit-app
Deploy to Cloud Run
gcloud run deploy my-streamlit-app \
  --image gcr.io/your-project-id/my-streamlit-app \
  --platform managed \
  --region us-central1 \
  --allow-unauthenticated

Best Practices for Deployment

  • Environment Variables: Use environment variables to manage secrets and configuration settings.
  • Logging: Implement logging to monitor your app’s performance and errors.
  • Security: Ensure your app is secure by handling user input appropriately and securing API keys.
  • Scalability: Choose deployment options that allow your app to scale with user demand.
  • Continuous Integration/Continuous Deployment (CI/CD): Set up CI/CD pipelines to automate the deployment process.

Managing Secrets and Configuration

Use environment variables to store sensitive information:

import os

API_KEY = os.getenv("API_KEY")

Set the environment variable in your deployment platform’s settings or configuration.

Implementing Logging

Use Python’s built-in logging library:

import logging

logging.basicConfig(level=logging.INFO)
logging.info("This is an info message")

Handling User Input Securely

Validate and sanitize all user inputs to prevent security vulnerabilities like injection attacks.

Summary

In this section, you’ve learned how to:

  • Run your Streamlit app outside of the development environment
  • Containerize your app using Docker for consistent deployments
  • Deploy your app to cloud platforms like Streamlit Community Cloud, Heroku, and AWS Elastic Beanstalk
  • Apply best practices for deploying and maintaining your Streamlit applications

By deploying your Streamlit app, you make it accessible to a wider audience, allowing others to benefit from your interactive data applications.

Best Practices and Tips

Developing Streamlit applications involves not just coding but also adhering to best practices that ensure your app is efficient, maintainable, and user-friendly. In this section, we’ll cover some essential tips and best practices to help you optimize your Streamlit apps.

Organizing Your Streamlit Codebase

A well-organized codebase enhances readability and maintainability, especially as your application grows in complexity.

Use Modular Code Structure

  • Separate Concerns: Break down your code into modules or scripts based on functionality, such as data loading, preprocessing, visualization, and utility functions.
  • Create a components Module: Encapsulate reusable UI components in a separate module to avoid code duplication.
  # components.py
  import streamlit as st

  def sidebar_filters():
      st.sidebar.header("Filters")
      # Add filter widgets
# main app.py
import streamlit as st
from components import sidebar_filters

sidebar_filters()
# Rest of your app code

Follow Naming Conventions

  • Consistent Naming: Use meaningful variable and function names that follow Python’s naming conventions.
  • Folder Structure: Organize files into folders such as data, models, utils, and pages if using Streamlit’s multipage apps.

Use Virtual Environments

  • Environment Isolation: Use virtual environments (e.g., venv, conda, or pipenv) to manage dependencies and avoid conflicts. Version Control

  • Git: Use Git for version control to track changes and collaborate with others.

  • .gitignore: Include a .gitignore file to exclude unnecessary files from your repository.

__pycache__/
.DS_Store
venv/
.env

Enhancing User Experience with Custom Themes and Layouts

A polished UI enhances the user experience and makes your app more engaging.

Custom Themes

  • Streamlit Themes: Customize the appearance of your app using Streamlit’s theming options.

  • Modify config.toml: Create a .streamlit/config.toml file to define your theme settings.

[theme]
primaryColor="#6eb52f"
backgroundColor="#f0f0f5"
secondaryBackgroundColor="#e0e0ef"
textColor="#262730"
font="sans serif"

Responsive Layouts

Use Columns and Containers: Organize content using st.columns(), st.container(), and st.expander() for a clean layout.

col1, col2 = st.columns(2)

with col1:
    st.header("Section 1")
    # Content for section 1

with col2:
    st.header("Section 2")
    # Content for section 2

Interactive Elements

Feedback: Use st.progress(), st.spinner(), and st.toast() to provide feedback during long computations.

with st.spinner('Loading data...'):
    df = load_data()
st.success('Data loaded successfully!')

Tooltips and Help Text: Add tooltips or help text to widgets to guide users.

st.text_input("Username", help="Enter your user ID assigned by the administrator")

Accessibility

Alt Text for Images: Use the caption parameter in st.image() to provide descriptions.

st.image('chart.png', caption='Sales over time')

Keyboard Navigation: Ensure that all interactive elements can be navigated using the keyboard.

Debugging Common Issues in Streamlit Apps

Being able to identify and fix issues quickly is crucial for smooth app development.

Common Issues and Solutions

App Crashes or Freezes
  • Infinite Loops: Ensure that your code doesn’t have infinite loops that can block the app. Large Data Loading: Use caching with @st.cache_data to prevent reloading data on every interaction.
Slow Performance
  • Heavy Computations: Optimize code by using efficient algorithms or leveraging libraries like NumPy and Pandas.
  • Caching: Use @st.cache_data and @st.cache_resource to cache expensive operations. Widget State Not Preserved
  • Session State: Use st.session_state to maintain state across interactions.
if 'counter' not in st.session_state:
    st.session_state.counter = 0

increment = st.button('Increment')
if increment:
    st.session_state.counter += 1

st.write(f"Counter: {st.session_state.counter}")

Errors When Deploying

Dependency Mismatches: Ensure that all dependencies are listed in requirements.txt and versions are compatible.

Environment Variables: Check that all required environment variables are set in the deployment environment.

Streamlit Version Issues

API Changes: If you encounter deprecated functions, update your code to match the latest Streamlit API.

Version Pinning: Specify the Streamlit version in your requirements.txt to maintain consistency.

streamlit==1.25.0

Logging and Error Tracking

Use Logging
import logging

logging.basicConfig(level=logging.INFO)
logging.info("This is an info message")
Display Errors

Use st.error() to display error messages to the user.

try:
    result = perform_calculation()
    st.write(result)
except Exception as e:
    st.error(f"An error occurred: {e}")

Testing

Unit Tests: Write unit tests for your functions using unittest or pytest. Test Scripts: Create test scripts to simulate user interactions and verify app behavior.

Performance Optimization

Optimizing your app’s performance ensures a better user experience.

Efficient Data Handling

Lazy Loading: Load data only when necessary, perhaps in response to user input. Data Sampling: For large datasets, consider using a sample for initial display and provide options to load more data.

Use of Caching

Cache Data Loading
@st.cache_data
def load_data():
    # Load data from source
    return data
Cache Computations
@st.cache_data
def compute_expensive_operation(params):
    # Perform computation
    return result

Optimize Resource Usage

Avoid Redundant Computations: Structure code to prevent unnecessary re-execution of functions.

Clear Session State When Needed: Manage st.session_state to free up memory if variables are no longer needed.

Security Considerations

Ensure your app is secure, especially when handling sensitive data.

Input Validation: Always validate and sanitize user inputs.

Secrets Management: Use Streamlit’s secrets management to handle API keys and passwords.

import os

API_KEY = st.secrets["api_key"]

HTTPS: Deploy your app using HTTPS to encrypt data in transit.

Documentation and User Guides

Provide documentation to help users understand and navigate your app.

Inline Documentation: Use st.markdown() or st.write() to include instructions and explanations within the app.

User Manuals: Provide a downloadable or linked user guide for complex applications.

Tooltips: Utilize the help parameter in widgets to give users quick hints.

Keep Up with Streamlit Updates

Streamlit is actively developed, and staying updated can help you leverage new features.

Changelog: Regularly check the Streamlit changelog for updates.

Community Forums: Participate in the Streamlit community forums to learn from others and share your experiences.

Update Dependencies: Periodically update your dependencies to benefit from performance improvements and security patches.

Summary

By following these best practices and tips, you can:

  • Enhance the maintainability and readability of your code.
  • Create a more engaging and user-friendly app interface.
  • Quickly identify and resolve issues during development.
  • Optimize your app’s performance for a better user experience.
  • Ensure the security and integrity of your application and data.

Implementing these strategies will help you develop professional, robust, and efficient Streamlit applications that meet the needs of your users and stakeholders.

Conclusion

In this comprehensive guide, we’ve embarked on a journey to master Streamlit using the Python Data Science Notebook Docker Image. Throughout the chapters, we’ve explored how to set up a robust environment, harness the power of Streamlit for building interactive data applications, and leverage advanced features to enhance functionality and user experience.

Recap of Key Learnings

  • Environment Setup: Established a consistent and portable development environment using Docker, ensuring all necessary libraries and tools are readily available.
  • Getting Started with Streamlit: Created our first Streamlit app, understanding the basic structure and core components that make up a Streamlit application.
  • Interactive Data Visualizations: Leveraged built-in Streamlit functions and integrated libraries like Altair and Plotly to build dynamic and interactive visualizations.
  • Advanced Features: Utilized state management with st.session_state, dynamic content creation with layout elements, and performance optimization through caching mechanisms.
  • Integrating Machine Learning Models: Loaded and interacted with machine learning models using TensorFlow, PyTorch, and scikit-learn, making predictions and visualizing outcomes within Streamlit apps.
  • Database Connectivity: Connected to various databases, including Dremio, PostgreSQL, and MySQL, using powerful libraries to query and manipulate data efficiently.
  • Deploying Streamlit Apps: Explored different deployment strategies, from running apps locally to containerizing with Docker and deploying on cloud platforms like Streamlit Community Cloud, Heroku, and AWS.
  • Best Practices and Tips: Emphasized the importance of code organization, user experience enhancements, debugging techniques, performance optimization, and security considerations to build professional and robust applications.

Next Steps to Further Explore Streamlit

While we’ve covered a significant amount of ground, there’s always more to learn and explore:

  • Dive Deeper into Streamlit Components: Experiment with custom components and the Streamlit Component API to extend the functionality of your apps.
  • Explore Streamlit’s Multipage Apps: Organize complex applications into multiple pages for better user navigation and structure.
  • Integrate Additional Libraries: Incorporate other data science and machine learning libraries to expand the capabilities of your applications.
  • Contribute to the Community: Share your apps and components with the Streamlit community, contribute to open-source projects, and engage in discussions to learn from others.

Additional Resources and Communities

  • Official Streamlit Documentation: docs.streamlit.io
  • Streamlit Forums: Engage with the community on the Streamlit Discourse platform.
  • Streamlit on GitHub: Explore the source code and contribute at github.com/streamlit/streamlit.
  • Tutorials and Courses: Look for online tutorials, courses, and webinars that cover advanced topics and real-world use cases.
  • Blogs and Articles: Follow blogs and articles by data science professionals who share insights and best practices.

Final Thoughts

Streamlit has revolutionized the way we create and share data applications, making it accessible for data scientists and developers to build interactive web apps with ease. By combining Streamlit with the Python Data Science Notebook Docker Image, we’ve established a powerful workflow that simplifies environment setup and accelerates application development.

As you continue your journey, remember that the key to mastery is consistent practice and exploration. Don’t hesitate to experiment with new ideas, seek feedback, and iterate on your applications. The world of data science is ever-evolving, and tools like Streamlit are at the forefront of making data more accessible and engaging for everyone.